JP4893400B2 - vending machine - Google Patents

Description

  The present invention relates to a vending machine that cools air circulating in a product storage chamber that stores products by absorbing heat in a cooling heat exchanger.

  There is a vending machine that defines a product storage room and a machine room inside, and stores the product in the product storage room, while storing the evaporator, compressor, condenser, and decompressor that constitute the refrigeration cycle in the machine room. Are known. The product storage chamber has a first opening (suction port) for supplying air from the product storage chamber to the machine chamber and a second opening (discharge port) for supplying air from the machine chamber to the product storage chamber. It is open. On the other hand, a wind passage is defined in the machine room extending from one side (suction side) to the other side (blowing side) with the evaporator at the center.

  A suction chamber is defined on the suction side of the air passage, and a suction port is opened in the suction chamber. The first opening opened in the product storage chamber and the suction port opened in the suction chamber are connected by a suction duct, and the product storage chamber and the suction chamber communicate with each other through the suction duct. For this reason, the air inside the product storage chamber is supplied to the suction chamber.

  On the other hand, a discharge chamber is defined on the blowing side of the wind passage, and a discharge port is opened in the discharge chamber. The discharge opening opened in the discharge chamber and the second opening opened in the product storage chamber are connected by a discharge duct, and the discharge chamber and the product storage chamber communicate with each other via the discharge duct. For this reason, the air inside the discharge chamber is supplied to the product storage chamber.

  A blower fan is disposed inside the discharge chamber. When the blower fan is driven, the air inside the product storage chamber is supplied from the product storage chamber to the suction chamber, the air inside the discharge chamber is supplied from the discharge chamber to the product storage chamber, and the air inside the product storage chamber is It circulates through an evaporator (for example, refer patent document 1 and patent document 2).

  By the way, the vending machine described above includes an internal heat exchanger that exchanges heat between the high-temperature refrigerant flowing out of the condenser and the low-temperature refrigerant flowing out of the evaporator in order to perform more efficient heat exchange. Is known. In this internal heat exchanger, since a pipe line (outer pipe) through which a low-temperature refrigerant flows is disposed around a pipe line (inner pipe) through which a high-temperature refrigerant flows, dew condensation occurs on the pipe surface. Become. In order to prevent such condensation, the internal heat exchanger is shielded with a heat insulating material or the like.

JP-A-3-286291 JP-A-3-286292

  However, shielding the internal heat exchanger with the heat insulating material in this way requires a heat insulating material in addition to the internal heat exchanger, which is an obstacle to cost reduction and space saving.

  An object of this invention is to provide the vending machine which can suppress the dew condensation in an internal heat exchanger, without shielding an internal heat exchanger with a heat insulating material in view of the said situation.

  In order to achieve the above object, a vending machine according to claim 1 of the present invention is such that one opens to one product storage for storing products and the other opens to a cooling chamber that stores a cooling heat exchanger. And a cool air suction duct for supplying air from one product storage to the cooling heat exchanger, and one of the openings opened in the cooling chamber and the other opened in the one product storage and cooled in the cooling heat exchanger In a vending machine having a cold air discharge duct for supplying a single product storage to a single product storage, the high-temperature refrigerant that has flowed out of the heating heat exchanger that constitutes the refrigeration cycle together with the cooling heat exchanger, and the cooling heat exchanger An internal heat exchanger for exchanging heat with the low-temperature refrigerant is housed in the cooling chamber.

  The vending machine according to claim 2 of the present invention is the vending machine according to claim 1, wherein the internal heat exchanger is provided with a pipe through which a low-temperature refrigerant flows around a pipe through which a high-temperature refrigerant flows. It is characterized by.

  The vending machine according to claim 3 of the present invention is the vending machine according to claim 1 or 2, wherein an evaporating dish is disposed below the cooling chamber, and drain water accumulated in the cooling chamber is discharged to the evaporating dish. It is characterized by that.

  In the vending machine according to the present invention, the internal heat exchanger that performs heat exchange between the high-temperature refrigerant that has flowed out of the heating heat exchanger and the cooling heat exchanger is accommodated in the cooling chamber. Is kept low, and condensation in the internal heat exchanger can be suppressed. Therefore, it is not necessary to shield the internal heat exchanger with a heat insulating material, and cost reduction and space saving can be achieved.

  Exemplary embodiments of a vending machine according to the present invention will be described below in detail with reference to the accompanying drawings. Note that the present invention is not limited to the embodiments.

  FIG. 1 is a front view showing a state in which an outer door and an inner door of a vending machine as an embodiment of the vending machine according to the present invention are opened, and FIG. 2 is a view of the vending machine II-II shown in FIG. FIG. 3 is a sectional view of the vending machine shown in FIG.

  The vending machine according to the embodiment of the present invention is a vending machine that sells products such as canned beverages, beverages in plastic bottles, or bottled beverages in a cooled state or in a warmed state. Is preferred.

  As shown in FIGS. 1 to 3, the vending machine according to the present embodiment includes a main body cabinet 1. The main body cabinet 1 is configured by appropriately combining a plurality of steel materials, and has a box shape with an open front surface.

  An inner door (not shown) and an outer door 2 are supported on the left edge of the main body cabinet 1. On the front surface of the outer door 2, a product display room (not shown) for displaying samples of products such as canned beverages and beverages in plastic bottles, a selection button (not shown) for selecting products, and money are displayed. Configurations necessary for the sale of merchandise such as a money slot (not shown) for throwing in and a merchandise outlet (not shown) for taking out the dispensed merchandise are arranged. The inner door is made of a heat insulating material, and is disposed between the outer door 2 and the main body cabinet 1 so as to open and close the front opening of the main body cabinet 1.

  The inside of the main body cabinet 1 is defined by a partition plate 3 (floor plate) into a product storage chamber 4 and a machine chamber 5. The product storage chamber 4 is defined in the upper part of the main body cabinet 1, and the machine room 5 is defined in the lower part of the main body cabinet 1.

  As shown in FIG. 1, the product storage chamber 4 is further divided into three product storages 4 a, 4 b, 4 c by two heat insulating partition plates 40. These three commodity storages 4 a, 4 b, 4 c are arranged side by side in the width direction of the main body cabinet 1. In the following description, the left-hand side product storage 4a is referred to as “left storage 4a”, the central product storage 4b as “center storage 4b”, and the right-hand product storage 4c as “right storage 4c”. Called.

  The left warehouse 4a and the middle warehouse 4b of the vending machine according to the present embodiment are cooling / heating storages that can both cool the product and warm the product, and the right store 4c only cools the product. It cannot be used for cooling.

  Further, in the vending machine according to the present embodiment, as shown in FIG. 1, the width (volume) of the right warehouse 4c is the largest, the width (volume) of the left warehouse 4a follows the right warehouse 4c, and the middle warehouse 4b. The width (volume) is defined to be the smallest. For this reason, two rows of product storage racks 6 are accommodated in the left cabinet 4a and right warehouse 4c in the width direction of the main body cabinet 1, and one row of product storage racks in the width direction of the main cabinet 1 are stored in the middle cabinet 4b. 6 is stored. The product storage rack 6 housed in the right box 4c and the product storage rack 6 housed in the left box 4a have different widths of the product storage rack 6, but this is usually different from the product storage rack 6 housed in the right box 4c. This is because it is possible to store a product such as a beverage in a plastic bottle having a capacity larger than the capacity of the bottle.

  As shown in FIGS. 2 and 3, the left storage 4a, the middle storage 4b, and the right storage 4c store product storage racks 6 so as to define five rows of product storage passages in the depth direction. . Therefore, 10 types of products can be stored in each of the left store 4a and the right store 4c, and five types of products can be stored in the middle store 4b. That is, the vending machine according to the present embodiment can store 25 types of products, and can sell them on demand.

  The product storage rack 6 is a so-called serpentine rack in which meandering product storage passages are defined. The product storage rack 6 carries out products one by one from the product storage rack 6 to the lower part of the product storage rack 6. A product unloading device (not shown) called a bendmec is provided.

  As shown in FIGS. 2 and 3, back ducts 41 are respectively attached to the interiors of the respective product storage boxes 4 a, 4 b, 4 c and at the depths of the product storage racks. The rear duct 41 is for sucking and circulating the air that has passed between the products stored in the product storage rack 6, and has a suction port (not shown) at a position in the middle of the product storage 4 a, 4 b, 4 c. And a discharge port is formed at a position below the product storages 4a, 4b, 4c.

  Moreover, as shown in FIG.4 and FIG.5, the interior wind tunnel 42a, 42b, 42c is attached to the lower back part of each goods storage 4a, 4b, 4c. The internal wind tunnels 42a, 42b, and 42c have a box shape in which the back surface and the bottom surface are opened, and the deep surfaces of the internal wind tunnels 42a, 42b, and 42c are connected to the discharge port of the back duct 41, The bottom surfaces of the internal wind tunnels 42a, 42b, and 42c are connected to the partition plate 3 (floor plate). Therefore, the air sucked from the suction port (not shown) of the rear duct 41 is guided to the internal wind tunnels 42a, 42b, and 42c via the discharge port of the rear duct 41.

  As shown in FIG.4 and FIG.5, among the goods storage 4a, 4b, 4c, the partition plate 3 (floor board) of the left warehouse 4a and the center warehouse 4b is a warm air inlet 43a in order toward the front from the back. 43b, cold air inlets 44a and 44b, cold air outlets 45a and 45b, and warm air outlets 46a and 46b are opened. The warm air inlets 43a and 43b and the cold air inlets 44a and 44b are open at the bottoms of the internal wind tunnels 42a and 42b, and the air sucked from the inlet (not shown) of the rear duct 41 is The air is sucked in from the warm air suction ports 43a and 43b or the cold air suction ports 44a and 44b via the discharge port of the rear duct 41 and the internal wind tunnels 42a and 42b. On the other hand, the cool air discharge ports 45a and 45b and the warm air discharge ports 46a and 46b are opened in front of the portions that are the bottom surfaces of the internal wind tunnels 42a and 42b, and the cool air discharge ports 45a and 45b or the warm air discharges. The air discharged from the outlets 46a and 46b is supplied directly into the left warehouse 4a or the middle warehouse 4b without directly flowing into the inner wind tunnels 42a and 42b.

  Warm air suction ports 43a, 43b, cool air suction ports 44a, 44b, cool air discharge ports 45a, 45b, warm air suction shutters 43a1, 43b1, cool air suction shutters 44a1, 44b1, and cool air discharge shutters 45a1, 45b1 and warm air discharge shutters 46a1 and 46b1 are provided in the left warehouse 4a and the middle warehouse 4b. These shutters are made of a heat insulating material, and are made of a plate-like body having an area sufficient to close the opening.

  The warm air suction shutters 43a1 and 43b1, the cold air suction shutters 44a1 and 44b1, the cool air discharge shutters 45a1 and 45b1, and the warm air discharge shutters 46a1 and 46b1 are linked to open and close. That is, when the warm air suction shutters 43a1 and 43b1 are linked to the warm air discharge shutters 46a1 and 46b1 and the warm air suction shutters 43a1 and 43b1 close the warm air suction ports 43a and 43b, the warm air discharge shutters 46a1 and 46b1 are warm air discharge ports 46a. 46b, the cool air suction shutters 44a1 and 44b1 are linked to the cool air discharge shutters 45a1 and 45b1, and the cool air suction shutters 44a1 and 44b1 close the cool air suction ports 44a and 44b. Closes the cold air discharge ports 45a and 45b.

  Further, the warm air suction shutters 43a1 and 43b1 and the warm air discharge shutters 46a1 and 46b1 and the cool air suction shutters 44a1 and 44b1 and the cool air discharge shutters 45a1 and 45b1 are also linked to open and close. That is, when the warm air suction shutters 43a1 and 43b1 close the warm air suction ports 43a and 43b and the warm air discharge shutters 46a1 and 46b1 close the warm air discharge ports 46a and 46b, the cold air suction shutters 44a1 and 44b1 become the cold air suction ports 44a and 44b. The cool air discharge shutters 45a1 and 45b1 open the cool air discharge ports 45a and 45b, while the cool air suction shutters 44a1 and 44b1 close the cool air suction ports 44a and 44b, and the cool air discharge shutters 45a1 and 45b1 cool the air discharge ports 45a. , 45b, the warm air suction shutters 43a1, 43b1 open the warm air suction ports 43a, 43b, and the warm air discharge shutters 46a1, 46b1 open the warm air discharge ports 46a, 46b.

  Therefore, when the left warehouse 4a is used as a cooling compartment, the warm air suction port 43a is closed and the warm air discharge port 46a is closed, while the cold air suction port 44a is opened and the cold air discharge port 45a is opened. Further, when the left chamber 4a is a heating chamber, the cold air suction port 44a is closed and the cold air discharge port 45a is closed, while the warm air suction port 43a is opened and the warm air discharge port 46a is opened. .

  Similarly, when the intermediate store 4b is a cooling store, the warm air suction port 43b is closed and the warm air discharge port 46b is closed, while the cold air suction port 44b is opened and the cold air discharge port 45b is opened. . Further, in the case where the intermediate store 4b is a heating store, the cool air suction port 44b is closed and the cool air discharge port 45b is closed, while the warm air suction port 43a is opened and the warm air discharge port 46b is opened. .

  Among the product storages 4a, 4b, and 4c, the partition plate 3 (floor plate) of the right store 4c has a cool air suction port 44c that opens in the middle and a cool air discharge port 45c that opens in the middle. . The cold air inlet 44c is open to a portion that becomes the bottom surface of the internal wind tunnel 42c, like the left warehouse 4a and the middle warehouse 4b, and the air sucked from the inlet (not shown) of the rear duct 41 is The rear duct 41 is sucked from the cold air inlet 44c via the discharge port (not shown) and the internal wind tunnel 42c. On the other hand, the cold air discharge port 45c is opened at a position ahead of the portion that is the bottom surface of the internal wind tunnel 42c, and the air discharged from the cold air discharge port 45c does not directly flow into the internal wind tunnel 42c. It is supplied into the right warehouse 4c.

  Since the right warehouse 4c is a cooling-only warehouse, it is not necessary to close the cold air inlet 44c and the cold air outlet 45c, and the cold air inlet 44c and the cold air outlet 45c are always open, so the cold air inlet 44c It is not necessary to provide the cool air suction shutter for closing the cool air and the cool air discharge shutter for closing the cold air discharge port 45c in the right box 4c.

  A product carry-out shooter 47 is attached to a part inside each product storage 4a, 4b, 4c and below the product storage rack 6. The product carry-out shooter 47 is for carrying the product carried out from the product storage rack 6 forward from the back of the product storage 4a, 4b, 4c, and is inclined so as to gradually become lower from the back toward the front. It is attached with.

  An internal fan 48 is attached to the lower surface of the product carry-out shooter 47. The internal fan 48 discharges air from the cool air discharge ports 45a, 45b, 45c or the warm air discharge ports 46a, 46b, and supplies air (cold air or warm air) to the products stored in the product storage rack 6. . The internal fan 48 attached to each product storage 4a, 4b, 4c is on / off controlled based on a temperature sensor (not shown) disposed in the product storage 4a, 4b, 4c. Thus, the temperature control of the product storages 4a, 4b, 4c is performed.

  As shown in FIGS. 4 and 5, four communication passages 5a, 5b, 5c, and 5d (ducts) are defined in the upper portion of the machine room 5, that is, the lower surface of the partition plate 3 by a heat insulating material. The communication passage (duct) extends in the juxtaposition direction of the product storages 4a, 4b, 4c, and in order from the back of the machine room 5 to the front, the warm air suction duct 5a, the cold air suction duct 5b, the cold air discharge duct 5c, A warm air discharge duct 5d is formed.

  One of the warm air suction ducts 5a opens into the product storage 4a, 4b, and the other opens into a heating chamber 81 that houses a heating heat exchanger 83 described later. Specifically, one of the warm air suction ducts 5a (suction side) opens to the warm air suction ports 43a and 43b of each product storage (left warehouse 4a, middle warehouse 4b), while the other (discharge side) of the warm air suction duct 5a. ) Opens to the heating chamber 81 in which the heating heat exchanger 83 is accommodated.

  One of the cold air suction ducts 5b opens into the commodity storage 4a, 4b, 4c, and the other opens into the cooling chamber 91 that houses a cooling heat exchanger 97 described later. Specifically, one side (suction side) of the cold air suction duct 5b opens to the cold air suction ports 44a, 44b, 44c of the respective product storages (left warehouse 4a, middle warehouse 4b, right warehouse 4c), while the cold air suction duct The other (discharge side) of 5b opens to the cooling chamber 91 in which the cooling heat exchanger 97 is accommodated.

  One of the cold air discharge ducts 5c opens into the cooling chamber 91, and the other opens into the product storage boxes 4a, 4b, 4c. Specifically, one side (suction side) of the cold air discharge duct 5c opens into the cooling chamber 91, while the other side (discharge side) of the cold air discharge duct 5c is each product storage (left store 4a, middle store 4b, right store). 4c) is opened to the cold air outlets 45a, 45b, 45c.

  One of the warm-air discharge ducts 5d opens into the heating chamber 81, and the other opens into the product storage boxes 4a and 4b. Specifically, one side (suction side) of the warm air discharge duct 5d opens into the heating chamber 81, while the other side (discharge side) of the warm air discharge duct 5d is the warm air of each product storage (left box 4a, middle box 4b). It opens to the discharge ports 46a and 46b.

  A heat exchange unit 7 is detachably attached to the machine room 5. As shown in FIG. 6, the heat exchange unit 7 includes a heating unit 8 and a cooling unit 9. The heating unit 8 has a box-shaped heating chamber 81 that is located on the left side of the front surface of the heat exchange unit 7 and is defined by a heat insulating material.

  As shown in FIG. 6, the upper surface of the heating chamber 81 is open, and the discharge side of the warm air suction duct 5a and the suction side of the warm air discharge duct 5d are open. Therefore, air is supplied to the heating chamber 81 from the product storage with the warm air inlets 43a and 43b open, and then air is supplied from the heating chamber 81 to the product storage with the warm air discharge ports 46a and 46b open. Will be.

  As shown in FIG. 7, the heating chamber 81 accommodates a compressor 82 and a heating heat exchanger 83. The compressor 82 compresses the refrigerant to a high temperature and high pressure state. For example, a two-stage compressor that performs a compression action in two steps is employed. The two-stage compressor includes a first compressor 82a and a second compressor 82b, and an intermediate heat exchanger 84 (first condenser) is provided between the first compressor 82a and the second compressor 82b. Intervene.

  The intermediate heat exchanger 84 is configured to dissipate the heat of condensation from the periphery of the intermediate heat exchanger 84 by condensing the refrigerant and to heat the air around the intermediate heat exchanger 84. The intermediate heat exchanger 84 includes, for example, a so-called fin-and-tube type condenser in which a copper tube penetrates an aluminum fin that is an aluminum plate-like body.

A heating heat exchanger 83 is connected to the compressor 82 (second compressor 82b). The heating heat exchanger 83 is configured to dissipate the heat of condensation of the heating heat exchanger by condensing the refrigerant and to heat the air around the heating heat exchanger 83. Note that when carbon dioxide (CO ₂ refrigerant) is used as a refrigerant as in the present embodiment, a supercritical state may occur without being liquefied. The heating heat exchanger 83 is constituted by, for example, a so-called fin-and-tube type condenser in which a copper tube passes through an aluminum fin that is an aluminum plate-like body.

  A gas cooler 85 (second condenser) is connected to the heating heat exchanger 83. The gas cooler 85 is configured to dissipate the heat of condensation around the gas cooler 85 by condensing the refrigerant in the same manner as the heating heat exchanger 83. The gas cooler 85 is configured by, for example, a so-called fin-and-tube type condenser in which a copper tube passes through an aluminum fin that is an aluminum plate-like body.

  The reason why the compressor 82 is accommodated in the heating chamber 81 in addition to the heating heat exchanger 83 is to collect the heat generated in the compressor 82 in addition to the heat radiated in the heating heat exchanger 83. is there.

  Further, the heating chamber 81 further accommodates a heating fan 86 and a heater 87. The heating fan 86 is disposed between the compressor 82 and the heating heat exchanger 83, and allows air to flow from the compressor 82 toward the heating heat exchanger 83. The heater 87 is disposed at a position in front of the heating heat exchanger 83. The heater 87 is located downstream of the heating heat exchanger 83 when the heating fan 86 is moved, and the heater 87 is used as a heater in the product storage box in which the warm air discharge ports 46a and 46b are opened from the heating chamber 81. Warm air will be supplied.

  The cooling unit 9 includes a box-shaped cooling chamber 91 that is located on the right side of the front surface of the heat exchange unit 7 and has an open upper surface, and an evaporating dish 92 disposed below the cooling chamber 91.

  As shown in FIG. 6, the cooling chamber 91 is defined by a heat insulating material, and the discharge side of the cold air suction duct 5b and the suction side of the cold air discharge duct 5c are open. Therefore, air is supplied to the cooling chamber 91 from the product storage with the cold air inlets 44a, 44b, 44c open, and then the product storage with the cool air discharge ports 45a, 45b, 45c open from the cooling chamber 91. Air will be supplied to.

  Furthermore, the water tray 93 is formed in the center part of the bottom wall in the aspect which becomes low gradually toward the center from the front and back. A drain 93a is provided at the lowest portion of the water receiving tray 93, and the drain water accumulated in the water receiving tray 93 is dropped onto the evaporating tray 92 through the drain 93a.

As shown in FIG. 7, an internal heat exchanger 94, an electronic expansion valve 95, an electromagnetic valve 96, and a cooling heat exchanger 97 are accommodated in the cooling chamber 91. The internal heat exchanger 94, the electronic expansion valve 95, the electromagnetic valve 96, and the cooling heat exchanger 97 together with the compressor 82 and the heating heat exchanger 83 housed in the heating chamber 81, as well as the intermediate heat exchanger 84 and the gas cooler 85. Configure the refrigeration cycle. In the present embodiment, carbon dioxide (CO ₂ refrigerant) that has nonflammability, safety, and corrosion resistance and has little influence on the ozone layer is used as the refrigerant that circulates in the refrigeration cycle configured as described above. ing.

  The internal heat exchanger 94 performs heat exchange between the high-temperature refrigerant flowing from the gas cooler 85 to the electronic expansion valve 95 and the low-temperature refrigerant flowing from the cooling heat exchanger 97 to the compressor 82, and is a high-temperature refrigerant. The refrigerant pipe 94b through which the low-temperature refrigerant flows is arranged around the refrigerant pipe 94a through which the refrigerant flows. That is, inside the internal heat exchanger 94, the refrigerant pipe 94a through which the refrigerant flows from the gas cooler 85 to the electronic expansion valve 95 and the refrigerant pipe 94b through which the refrigerant flows from the cooling heat exchanger 97 to the compressor 82 exchange heat with each other. It is arranged in a non-contact countercurrent manner at a possible distance.

  The electronic expansion valve 95 is connected to the internal heat exchanger 94 via a refrigerant pipe, and adiabatically expands the refrigerant radiated in the gas cooler 85. The adiabatically expanded refrigerant is decompressed to a low temperature and a low pressure.

  The electromagnetic valve 96 is connected to the electronic expansion valve 95 via a refrigerant pipe, and discharges the refrigerant to the cooling heat exchanger 97 in the open state, while blocking the refrigerant in the closed state.

  The cooling heat exchanger 97 is connected to the electromagnetic valve 96 through the refrigerant pipe, and absorbs the heat of evaporation from the periphery of the cooling heat exchanger 97 by evaporating the refrigerant adiabatically expanded to a low temperature and low pressure state. The air around the cooling heat exchanger 97 is cooled. The cooling heat exchanger 97 is constituted by, for example, a so-called fin-and-tube type evaporator in which a copper tube passes through an aluminum fin that is an aluminum plate.

  In the cooling chamber 91, a wind shielding member 91 a is disposed between the internal heat exchanger 94 and the cooling heat exchanger 97. The wind shield member 91a is for suppressing the inflow of air from the periphery of the cooling heat exchanger 97 to the periphery of the internal heat exchanger 97, and the interior of the cooling chamber 91 communicates below the wind shield member 91a. Yes.

  The evaporating dish 92 is for accumulating dripped drain water and promoting the evaporation of the drain water. The evaporating dish 92 is provided with an evaporating sheet 98 in which a nonwoven fabric is folded. Further, an evaporation promoting fan 99 is provided at a position behind the evaporating dish 92. The evaporation promotion fan 99 can promote the evaporation of drain water sucked up by the evaporation sheet 98 by capillary action.

  According to the heat exchange unit described above, the refrigerant is compressed in the compressor 82 and the intermediate heat exchanger 84 to be in a high temperature and high pressure state. Specifically, the refrigerant compressed by the first (first) compression action in the first compressor 82a is cooled in the intermediate heat exchanger 84 and then supplied to the second compressor 82b. Therefore, since the refrigerant is cooled between the first compressor 82a and the second compressor 82b, that is, in the intermediate heat exchanger 84, the refrigerant is compressed to a desired high temperature and high pressure state with low power consumption.

  The refrigerant that has been compressed in the compressor 82 and the intermediate heat exchanger 84 and is in a high-temperature and high-pressure state is discharged to the heating heat exchanger 83, dissipates heat in the heating heat exchanger 83, and surrounds the heating heat exchanger 83. Heat the air.

  The refrigerant radiated in the heating heat exchanger 83 is discharged to the gas cooler 85 and further radiates heat (exhaust heat) in the gas cooler 85. The refrigerant radiated by the gas cooler 85 is discharged to the electronic expansion valve 95 via the internal heat exchanger 94. In the internal heat exchanger 94, heat exchange is performed between the high-pressure refrigerant discharged from the gas cooler 85 to the electronic expansion valve 95 and the low-pressure refrigerant discharged from the cooling heat exchanger 97 to the compressor 82.

  The refrigerant discharged to the electronic expansion valve 95 is decompressed, adiabatically expanded, and is in a low temperature and low pressure state. The low-temperature and low-pressure refrigerant is discharged to the cooling heat exchanger 97 via the electromagnetic valve 96 in the open state.

  The refrigerant that has reached a low temperature and low pressure state in the electronic expansion valve 95 is evaporated and vaporized in the cooling heat exchanger 97. At this time, heat is absorbed from the periphery of the cooling heat exchanger 97, and the air around the cooling heat exchanger 97 is cooled.

  The heat exchange unit 7 thus configured is provided with a pair of left and right pop-up handles (not shown). The pop-up handle is for popping up (raising) the heat exchanging unit 7 housed in the machine room 5, and the pop-up handles are in opposite directions (the left pop-up handle is counterclockwise and the right pop-up handle is clockwise). The heat exchanging unit 7 pops up (rises) when it is rotated to be.

  After the heat exchange unit 7 configured as described above is accommodated in the machine room 5, the pop-up handles are rotated in opposite directions (the left pop-up handle is counterclockwise and the right pop-up handle is clockwise). When the heat exchange unit 7 is popped up (raised) by moving, the other of the warm air suction duct 5a (discharge side) and one of the warm air discharge duct 5d (suction side) open to the heating chamber 81, and the cold air suction duct The other of 5 b (discharge side) and one of the cool air discharge ducts 5 c (suction side) open into the cooling chamber 91. The warm air suction duct 5a and the warm air discharge duct 5d are in close contact with the upper surface opening of the heating chamber 81, the cold air suction duct 5b and the cool air discharge duct 5c and the opening of the cooling chamber 91 are in close contact, and the heat exchange unit 7 and the warm air suction duct. Air does not leak between 5a, the cool air suction duct 5b, the cool air discharge duct 5c, and the warm air discharge duct 5d.

  As shown in FIG. 8, in the vending machine according to the embodiment of the present invention described above, when the products are cooled in all the product storages 4a, 4b, 4c, that is, the left store 4a, the middle store 4b, the right store. When the product is cooled in 4c (the state in which the vending machine is set in this way is referred to as “CCC mode”), the warm air suction ports 43a and 43b and the warm air discharge ports 46a and 46b of the left and right warehouses 4a and 4b are closed. At the same time, the cold air inlets 44a and 44b and the cold air outlets 45a and 45b of the left warehouse 4a and the middle warehouse 4b are opened.

  And the internal fan 48 until the temperature sensor (not shown) arrange | positioned in each store | warehouse | chamber (left store 4a, middle store 4b, right store 4c) of goods storage becomes a set temperature (for example, 5 degrees C). Turn on. Then, the air cooled in the cooling chamber 91 circulates in the product storage where the internal fan 48 is turned on, and the product is cooled in all of the left store 4a, the middle store 4b, and the right store 4c. Become. Then, the internal temperature decreases with the passage of time, and when the internal fan 48 is turned off, the internal temperature increases with the passage of time. By repeating this, the internal temperature is kept at the set temperature. First, the internal temperature of the intermediate store 4b reaches the set temperature, and then the internal temperatures of the left store 4a and the right store 4c reach the set temperature. For this reason, after the internal fan 48 of the central warehouse 4b is turned off, the internal fan 48 of the left warehouse 4a and the internal fan 48 of the right warehouse 4c are turned off.

  On the other hand, when warming the product in the left store 4a and cooling the product in the middle store 4b and the right store 4c (the state in which the vending machine is set in this way is referred to as “HCC mode”), the cold air inlet of the left store 4a 44a and the cool air discharge port 45a are closed, while the warm air suction port 43a and the warm air discharge port 46a of the left chamber 4a are opened, and the warm air suction port 43b and the warm air discharge port 46b of the center chamber 4b are closed. The cold air inlet 44b and the cold air outlet 45b of the warehouse 4b are opened.

  And the temperature sensor (not shown) arrange | positioned in each store | warehouse | chamber (left store 4a, middle store 4b, right store 4c) of goods storage is set temperature (for example, left store is 55 degrees C, middle store, and right store) Until the temperature reaches 5 ° C.). Then, the air warmed in the heating chamber 81 circulates in the left warehouse 4a in which the internal fan 48 is turned on, and the product is warmed in the left warehouse 4a. On the other hand, the air cooled in the cooling chamber 91 circulates in the middle warehouse 4b and the right warehouse 4c in which the internal fan 48 is turned on, and the product is cooled in the middle warehouse 4b and the right warehouse 4c. And as time passes, the internal temperature of the left warehouse 4a increases, and the internal temperature of the intermediate warehouse 4b and the right warehouse 4c decreases. When the internal fan 48 is turned off, the internal temperature of the left storage 4a decreases, and the internal temperatures of the central storage 4b and the right storage 4c increase. By repeating this, the internal temperature is kept at the set temperature. First, the internal temperature of the right compartment 4c reaches the set temperature, and the internal temperature reaches the set temperature in the order of the left compartment 4a and the middle compartment 4b. For this reason, after the internal fan 48 of the right warehouse 4c and the internal fan 48 of the left warehouse 4a are turned off in this order, the internal fan 48 of the middle warehouse 4b is turned off.

  When the vending machine is operated in the HCC mode, heating in the heating chamber 81 and cooling in the cooling chamber 91 are started at the same time, and thereafter, heating in the heating chamber 81 is interrupted while cooling in the cooling chamber 91 is performed. Control to continue.

  On the other hand, when the product is warmed in the left store 4a and the center store 4b and the product is cooled in the right store 4c (the state in which the vending machine is set in this way is referred to as “HHC mode”), the left store 4a and the center store 4b. The cool air suction ports 44a and 44b and the cool air discharge ports 45a and 45b are closed, while the warm air suction ports 43a and 43b and the warm air discharge ports 46a and 46b of the left and right chambers 4a and 4b are opened.

  And the temperature sensor (not shown) arrange | positioned in merchandise storage (left warehouse 4a, middle warehouse 4b, right warehouse 4c) is set temperature (For example, left warehouse and inner warehouse are 55 degreeC, right warehouse is 5 degrees. The internal fan 48 is turned on until C). Then, the air warmed in the heating chamber 81 circulates in the left warehouse 4a and the middle warehouse 4b in which the internal fan 48 is turned on, and the product is warmed in the left warehouse 4a and the middle warehouse 4b. On the other hand, the air cooled in the cooling chamber 91 circulates in the right store 4c where the internal fan 48 is turned on, and the product is cooled in the right store 4c. As the time passes, the internal temperature of the left warehouse 4a and the middle warehouse 4b increases, and the internal temperature of the right warehouse 4c decreases. When the internal fan 48 is turned off, the internal temperature of the left storage 4a and the central storage 4b decreases, and the internal temperature of the right storage 4c increases. By repeating this, the internal temperature is kept at the set temperature. First, the internal temperature of the middle warehouse 4b and the right warehouse 4c reaches the set temperature, and then the internal temperature of the left warehouse 4a reaches the set temperature. For this reason, after the internal fan 48 of the central warehouse 4b and the internal fan 48 of the right warehouse 4c are turned off, the internal fan 48 of the intermediate warehouse 4b is turned off.

  When operating the vending machine in the HHC mode, the heating in the heating chamber 81 and the cooling in the cooling chamber 91 are started simultaneously, and then the cooling in the cooling chamber 91 is interrupted while the heating in the heating chamber 81 is continued. To control (only heating operation). At this time, while the compressor 82 is stopped, the heater 87 is operated. Therefore, excessive heat of evaporation is not absorbed in the cooling chamber 91, and it is not necessary to discharge the cooled air to the outside of the vending machine.

  When warming the product in the central store 4b and cooling the product in the left store 4a and the right store 4c (the state in which the vending machine is set in this way is referred to as “CHC mode”), the warm air inlet of the left store 4a 43a and warm air outlet 46a are closed, while cold air inlet 44a and cold air outlet 45a of left warehouse 4a are opened, while cold air inlet 44b and cold air outlet 45b of middle warehouse 4b are closed, The warm air suction port 43b and the warm air discharge port 46b of the storage 4b are opened.

  And the temperature sensor (not shown) arrange | positioned in goods storage (left warehouse 4a, middle warehouse 4b, right warehouse 4c) is set temperature (for example, 55 degreeC in the middle warehouse, 5 degrees in the left warehouse and the right warehouse). The internal fan 48 is turned on until C). Then, the air warmed in the heating chamber 81 circulates in the middle store 4b where the internal fan 48 is turned on, and the product is warmed in the middle store 4b. On the other hand, the air cooled in the cooling chamber 91 circulates in the left warehouse 4a and the right warehouse 4c where the internal fan 48 is turned on, and the product is cooled in the left warehouse 4a and the right warehouse 4c. Then, with the passage of time, the internal temperature of the middle warehouse 4b increases, and the internal temperature of the left warehouse 4a and the right warehouse 4c decreases. When the internal fan 48 is turned off, the internal temperature of the intermediate storage 4b decreases, and the internal temperatures of the left storage 4a and the right storage 4c increase. By repeating this, the internal temperature is kept at the set temperature. In addition, the internal temperature of the left store | warehouse | chamber 4a and the right store | warehouse | chamber 4c reaches | attains preset temperature first, and the internal chamber temperature of the central store | warehouse | chamber 4b reaches | attains preset temperature first. For this reason, after the internal fan 48 of the left warehouse 4a and the internal fan 48 of the right warehouse 4c are turned off, the internal fan 48 of the intermediate warehouse 4b is turned off.

  When operating the vending machine in the CHC mode, the heating in the heating chamber 81 and the cooling in the cooling chamber 91 are started simultaneously, and then the cooling in the cooling chamber 91 is interrupted while the heating in the heating chamber 81 is continued. To control (only heating operation). At this time, while the compressor 82 is stopped, the heater 87 is operated. Therefore, excessive heat of evaporation is not absorbed in the cooling chamber 91, and it is not necessary to discharge the cooled air to the outside of the vending machine.

  The vending machine according to the present embodiment described above is an internal heat exchanger that performs heat exchange between the high-temperature refrigerant flowing from the gas cooler 85 to the electronic expansion valve 95 and the low-temperature refrigerant flowing from the cooling heat exchanger 97 to the compressor. Since the container 94 is accommodated in the cooling chamber 91, dew condensation in the internal heat exchanger 94 can be suppressed. As a result, it is not necessary to shield the internal heat exchanger 94 with a heat insulating material, which can contribute to cost reduction and space saving. Even if condensation occurs in the internal heat exchanger 94, it can be discharged to the evaporating dish 92 via the water receiving tray 93 and the drain 93a.

  Further, the internal heat exchanger 94 has a configuration in which the refrigerant pipe through which the low-temperature refrigerant flows is arranged around the refrigerant pipe through which the high-temperature refrigerant flows. Therefore, the internal heat exchanger 94 has a high temperature around the refrigerant pipe through which the low-temperature refrigerant flows. The pressure loss can be reduced as compared with the case where the refrigerant pipe through which the refrigerant flows is provided, and efficient heat exchange can be performed.

  Further, a water receiving tray 93 is formed on the bottom wall that defines the cooling chamber 91, and the drain water accumulated in the water receiving tray 93 is dripped into the evaporating tray through the drain. The drain water generated by the defrosting operation of the exchanger 97 and the condensed water condensed on the internal heat exchanger 94 can be discharged to the outside of the cooling chamber 91.

It is a front view of the vending machine which is embodiment of this invention, Comprising: The state which removed the outer door and the inner door is shown. It is a vertical side view which shows the vending machine longitudinally cut in the II-II line in FIG. It is a vertical side view which shows the vending machine longitudinally cut in the III-III line in FIG. It is a perspective view for demonstrating circulation of cold air. It is a perspective view for demonstrating circulation of warm air. It is a perspective view which shows the heat exchange unit attached to the vending machine shown in FIG. 1 so that attachment or detachment is possible. It is a circuit diagram which shows the refrigerant circuit of the heat exchange unit shown in FIG. It is a figure explaining the operating state of the vending machine which is embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Main body cabinet 2 Outer door 3 Partition plate 4 Goods storage room 4a Left warehouse (goods storage)
4b Nakago (product storage)
4c Right warehouse (product storage)
40 heat insulation partition plate 41 rear duct 42a, 42b, 42c interior wind tunnel 43a, 43b warm air suction port 43a1, 43b1 warm air suction shutter 44a, 44b, 44c cold air suction port 44a1, 44b1 cold air suction shutter 45a, 45b, 45c cool air discharge port 45a1, 45b1 Cold air discharge shutter 46a, 46b Warm air discharge port 46a1, 46b1 Warm air discharge shutter 47 Product carry-out shooter 48 Internal fan 5 Machine room 5a Warm air intake duct 5b Cold air intake duct 5c Cold air discharge duct 5d Warm air discharge duct 6 Product storage rack 7 Heat exchange unit 8 Heating unit 81 Heating chamber 82 Compressor 82a First compressor 82b Second compressor 83 Heating heat exchanger 84 Intermediate heat exchanger 85 Gas cooler 86 Heating fan 87 Heater 9 Cooling unit 91 Cooling chamber 91a Wind shield member 92 evaporation Dish 93 Water tray 93a Drain 94 Internal heat exchanger 94a Refrigerant line 94b Refrigerant line 95 Electronic expansion valve 96 Electromagnetic valve 97 Cooling heat exchanger 98 Evaporating sheet 99 Evaporation promoting fan

Claims (3)

A cold air suction duct that opens to one product storage for storing products and the other opens to a cooling chamber that stores the cooling heat exchanger, and supplies air from the one product storage to the cooling heat exchanger; In a vending machine provided with a cold air discharge duct that opens to one product storage and the other opens to one product storage and supplies the air cooled in the cooling heat exchanger to the one product storage,
An internal heat exchanger for exchanging heat between the high-temperature refrigerant flowing out of the heating heat exchanger constituting the refrigeration cycle together with the cooling heat exchanger and the low-temperature refrigerant flowing out of the cooling heat exchanger is provided in the cooling chamber. Vending machine characterized by being housed.   The vending machine according to claim 1, wherein the internal heat exchanger is provided with a pipe line through which a low-temperature refrigerant flows around a pipe line through which a high-temperature refrigerant flows.   The vending machine according to claim 1 or 2, wherein an evaporating dish is disposed below the cooling chamber, and drain water accumulated in the cooling chamber is discharged to the evaporating dish.

Images